{-# LANGUAGE BlockArguments #-} {-# LANGUAGE LambdaCase #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE DerivingStrategies #-} {-# LANGUAGE DeriveAnyClass #-} {-# LANGUAGE ViewPatterns #-} {-# LANGUAGE CPP #-} {-# LANGUAGE ConstraintKinds #-} {-# LANGUAGE KindSignatures #-} {-# OPTIONS_GHC -fno-full-laziness #-} module Elab.WiredIn ( wiType , wiValue , wiredInNames , NoSuchPrimitive(..) , iand , ior , inot , ielim , incS , outS , comp , fill , hComp , glueType , glueElem , unglue , fun , system , strictK , strictJ , projIntoCase ) where import Control.Exception ( assert, Exception ) import qualified Data.Map.Strict as Map import qualified Data.Sequence as Seq import qualified Data.Text as T import Data.Map.Strict (Map) import Data.Text (Text) import Data.Typeable import Debug import Elab.Eval import GHC.Stack (HasCallStack) import Presyntax.Presyntax (Plicity(Im, Ex)) import qualified Presyntax.Presyntax as P import Syntax.Pretty (prettyTm, prettyVl) import Syntax import System.IO.Unsafe ( unsafePerformIO ) wiType :: WiredIn -> NFType wiType WiType = VType wiType WiPretype = VTypeω wiType WiInterval = VTypeω wiType WiI0 = VI wiType WiI1 = VI wiType WiIAnd = VI ~> VI ~> VI wiType WiIOr = VI ~> VI ~> VI wiType WiINot = VI ~> VI wiType WiPathP = dprod (VI ~> VType) \a -> a @@ VI0 ~> a @@ VI1 ~> VType wiType WiPartial = VI ~> VType ~> VTypeω wiType WiPartialP = dprod VI \x -> VPartial x VType ~> VTypeω wiType WiPOr = forAll VType \a -> dprod VI \phi -> dprod VI \psi -> VPartial phi a ~> VPartial psi a ~> VPartial (ior phi psi) a wiType WiSub = dprod VType \a -> dprod VI \phi -> VPartial phi a ~> VTypeω wiType WiInS = forAll VType \a -> forAll VI \phi -> dprod a \u -> VSub a phi (fun (const u)) wiType WiOutS = forAll VType \a -> forAll VI \phi -> forAll (VPartial phi a) \u -> VSub a phi u ~> a wiType WiComp = dprod' "A" (VI ~> VType) \a -> forAll VI \phi -> dprod (dprod VI \i -> VPartial phi (a @@ i)) \u -> VSub (a @@ VI0) phi (u @@ VI0) ~> VSub (a @@ VI1) phi (u @@ VI1) wiType WiGlue = dprod' "A" VType \a -> forAll' "phi" VI \phi -> dprod' "T" (VPartial phi VType) \t -> VPartialP phi (fun \o -> equiv (t @@ o) a) ~> VType wiType WiGlueElem = forAll' "A" VType \a -> forAll' "phi" VI \phi -> forAll' "T" (VPartial phi VType) \ty -> forAll' "e" (VPartialP phi (fun \o -> equiv (ty @@ o) a)) \eqv -> dprod' "t" (VPartialP phi ty) \t -> VSub a phi (fun \o -> vProj1 (eqv @@ o) @@ (t @@ o)) ~> VGlueTy a phi ty eqv wiType WiUnglue = forAll' "A" VType \a -> forAll' "phi" VI \phi -> forAll' "T" (VPartial phi VType) \ty -> forAll' "e" (VPartialP phi (fun \o -> equiv (ty @@ o) a)) \e -> VGlueTy a phi ty e ~> a wiType WiSEq = forAll' "A" VTypeω \a -> a ~> a ~> VTypeω wiType WiSRefl = forAll' "A" VTypeω \a -> forAll' "x" a \x -> VEqStrict a x x wiType WiSK = forAll' "A" VTypeω \a -> forAll' "x" a \x -> dprod' "P" (VEqStrict a x x ~> VTypeω) \bigp -> (bigp @@ VReflStrict a x) ~> dprod' "p" (VEqStrict a x x) \p -> bigp @@ p wiType WiSJ = forAll' "A" VTypeω \a -> forAll' "x" a \x -> dprod' "P" (dprod' "y" a \y -> VEqStrict a x y ~> VTypeω) \bigp -> bigp @@ x @@ VReflStrict a x ~> forAll' "y" a \y -> dprod' "p" (VEqStrict a x y) \p -> bigp @@ y @@ p wiType WiLineToEquiv = dprod' "P" (VI ~> VType) \a -> equiv (a @@ VI0) (a @@ VI1) wiValue :: WiredIn -> Value wiValue WiType = VType wiValue WiPretype = VTypeω wiValue WiInterval = VI wiValue WiI0 = VI0 wiValue WiI1 = VI1 wiValue WiIAnd = functions [(Ex, "i"), (Ex, "j")] \[i, j] -> iand i j wiValue WiIOr = functions [(Ex, "i"), (Ex, "j")] \[i, j] -> ior i j wiValue WiINot = fun' "x" inot wiValue WiPathP = functions [(Ex, "A"), (Ex, "x"), (Ex, "y")] \[a, x, y] -> VPath a x y wiValue WiPartial = functions [(Ex, "phi"), (Ex, "A")] \[phi, a] -> VPartial phi a wiValue WiPartialP = functions [(Ex, "phi"), (Ex, "A")] \[phi, a] -> VPartialP phi a wiValue WiPOr = functions [(Im, "A"), (Ex, "phi"), (Ex, "psi"), (Ex, "a"), (Ex, "b")] \[_, phi, psi, a, b] -> mkVSystem (Map.fromList [(phi, a), (psi, b)]) wiValue WiSub = functions [(Ex, "A"), (Ex, "phi"), (Ex, "u")] \[a, phi, u] -> VSub a phi u wiValue WiInS = functions [(Im, "A"), (Im, "phi"), (Ex, "u")] \[a, phi, u] -> incS a phi u wiValue WiOutS = functions [(Im, "A"), (Im, "phi"), (Im, "u"), (Ex, "u0")] \[a, phi, u, x] -> outS a phi u x wiValue WiComp = fun' "A" \a -> forallI \phi -> fun' "u" \u -> fun' "u0" \x -> incS (a @@ VI1) phi (comp a phi u x) wiValue WiGlue = fun \a -> forallI \phi -> fun \t -> fun \e -> glueType a phi t e wiValue WiGlueElem = forallI \a -> forallI \phi -> forallI \ty -> forallI \eqv -> fun \x -> fun \y -> glueElem a phi ty eqv x y wiValue WiUnglue = forallI \a -> forallI \phi -> forallI \ty -> forallI \eqv -> fun \x -> unglue a phi ty eqv x wiValue WiSEq = forallI \a -> fun \x -> fun \y -> VEqStrict a x y wiValue WiSRefl = forallI \a -> forallI \x -> VReflStrict a x wiValue WiSK = forallI \a -> forallI \x -> fun \bigp -> fun \pr -> fun \p -> strictK a x bigp pr p wiValue WiSJ = forallI \a -> forallI \x -> fun \bigp -> fun \pr -> forallI \y -> fun \p -> strictJ a x bigp pr y p wiValue WiLineToEquiv = fun \l -> GluedVl (HVar (Defined "lineToEquiv" (-1))) (Seq.fromList [(PApp P.Ex l)]) (makeEquiv' ((l @@) . inot)) (~>) :: Value -> Value -> Value a ~> b = VPi P.Ex a (Closure (Bound "_" 0) (const b)) infixr 7 ~> fun, line :: (Value -> Value) -> Value fun k = VLam P.Ex $ Closure (Bound "x" 0) (k . force) line k = VLam P.Ex $ Closure (Bound "i" 0) (k . force) fun' :: String -> (Value -> Value) -> Value fun' x k = VLam P.Ex $ Closure (Bound (T.pack x) 0) (k . force) functions :: [(P.Plicity, String)] -> ([Value] -> Value) -> Value functions args cont = go args [] where go [] acc = cont (reverse acc) go ((p, x):xs) acc = VLam p $ Closure (Bound (T.pack x) 0) \arg -> go xs (arg:acc) forallI :: (Value -> Value) -> Value forallI k = VLam P.Im $ Closure (Bound "x" 0) (k . force) dprod' :: String -> Value -> (Value -> Value) -> Value dprod' t a b = VPi P.Ex a (Closure (Bound (T.pack t) 0) b) dprod :: Value -> (Value -> Value) -> Value dprod = dprod' "x" exists' :: String -> Value -> (Value -> Value) -> Value exists' s a b = VSigma a (Closure (Bound (T.pack s) 0) b) exists :: Value -> (Value -> Value) -> Value exists = exists' "x" forAll' :: String -> Value -> (Value -> Value) -> Value forAll' n a b = VPi P.Im a (Closure (Bound (T.pack n) 0) b) forAll :: Value -> (Value -> Value) -> Value forAll = forAll' "x" wiredInNames :: Map Text WiredIn wiredInNames = Map.fromList [ ("Pretype", WiPretype) , ("Type", WiType) , ("Interval", WiInterval) , ("i0", WiI0) , ("i1", WiI1) , ("iand", WiIAnd) , ("ior", WiIOr) , ("inot", WiINot) , ("PathP", WiPathP) , ("Partial", WiPartial) , ("PartialP", WiPartialP) , ("partialExt", WiPOr) , ("Sub", WiSub) , ("inS", WiInS) , ("outS", WiOutS) , ("comp", WiComp) , ("Glue", WiGlue) , ("glue", WiGlueElem) , ("unglue", WiUnglue) , ("Eq_s", WiSEq) , ("refl_s", WiSRefl) , ("K_s", WiSK) , ("J_s", WiSJ) , ("lineToEquiv", WiLineToEquiv) ] newtype NoSuchPrimitive = NoSuchPrimitive { getUnknownPrim :: Text } deriving (Show, Typeable) deriving anyclass (Exception) iand, ior :: Value -> Value -> Value iand x = case force x of VI1 -> id VI0 -> const VI0 VIAnd x y -> \z -> case force z of VI0 -> VI0 VI1 -> VI1 z -> iand x (iand y z) x -> \y -> case force y of VI0 -> VI0 VI1 -> x y -> VIAnd x y ior x = case force x of VI0 -> id VI1 -> const VI1 VIOr x y -> \z -> case force z of VI1 -> VI1 VI0 -> VIOr x y _ -> ior x (ior y z) x -> \y -> case force y of VI1 -> VI1 VI0 -> x y -> VIOr x y inot :: Value -> Value inot x = case force x of VI0 -> VI1 VI1 -> VI0 VIOr x y -> VIAnd (inot x) (inot y) VIAnd x y -> VIOr (inot x) (inot y) VINot x -> x x -> VINot x ielim :: Value -> Value -> Value -> Value -> NFEndp -> Value ielim line left right (GluedVl h sp vl) i = GluedVl h (sp Seq.:|> PIElim line left right i) (ielim line left right vl i) ielim line left right fn i = case force fn of VLine _ _ _ fun -> fun @@ i VLam _ (Closure _ k) -> k i x -> case force i of VI1 -> right VI0 -> left _ -> case x of VNe n sp -> VNe n (sp Seq.:|> PIElim line left right i) VSystem map -> VSystem (fmap (flip (ielim line left right) i) map) VInc (VPath _ _ _) _ u -> ielim line left right u i VCase env r x xs -> VCase env r x (fmap (projIntoCase (flip (IElim (quote line) (quote left) (quote right)) (quote i))) xs) _ -> error $ "can't ielim " ++ show (prettyTm (quote fn)) incS :: DebugCallStack => NFSort -> NFEndp -> Value -> Value incS _ _ (force -> VNe h (sp Seq.:|> POuc _ _ _)) = VNe h sp incS a phi u = VInc a phi u outS :: DebugCallStack => NFSort -> NFEndp -> Value -> Value -> Value outS _ (force -> VI1) u _ = u @@ VReflStrict VI VI1 outS _ _phi _ (VInc _ _ x) = x outS _ VI0 _ x = x outS a phi u (GluedVl x sp vl) = GluedVl x (sp Seq.:|> POuc a phi u) (outS a phi u vl) outS a phi u (VNe x sp) = VNe x (sp Seq.:|> POuc a phi u) outS a phi u (VSystem fs) = mkVSystem (fmap (outS a phi u) fs) outS _ _ _ v = error $ "can't outS " ++ show (prettyTm (quote v)) comp :: DebugCallStack => NFLine -> NFEndp -> Value -> Value -> Value comp _a (force -> VI1) u _a0 = u @@ VI1 @@ VReflStrict VI VI1 comp a psi@phi u incA0@(outS (a @@ VI0) phi (u @@ VI0) -> a0) = case force (a @@ VVar name) of VPi{} -> let plic i = let VPi p _ _ = force (a @@ i) in p dom i = let VPi _ d _ = force (a @@ i) in d rng i = let VPi _ _ (Closure _ r) = force (a @@ i) in r y' i y = fill (fun (dom . inot)) VI0 (fun \_ -> fun \_ -> VSystem mempty) (incS (dom VI0) phi y) i ybar i y = y' (inot i) y in VLam (plic VI1) . Closure (Bound "x" 0) $ \arg -> comp (line \i -> rng i (ybar i arg)) phi (system \i isone -> vApp (plic i) (u @@ i @@ isone) (ybar i arg)) (incS (rng VI0 (ybar VI0 arg)) phi (vApp (plic VI0) a0 (ybar VI0 arg))) VSigma{} -> let dom i = let VSigma d _ = force (a @@ i) in d rng i = let VSigma _ (Closure _ r) = force (a @@ i) in r w i = fill (fun dom) phi (system \i isone -> vProj1 (u @@ i @@ isone)) (incS (dom VI0) phi (vProj1 a0)) i c2 = comp (fun \x -> rng x (w x)) phi (system \i isone -> vProj2 (u @@ i @@ isone)) (incS (rng VI0 (w VI0)) phi (vProj2 a0)) in VPair (w VI1) c2 VPath{} -> let a' i = let VPath thea _ _ = force (a @@ i) in thea u' i = let VPath _ theu _ = force (a @@ i) in theu v' i = let VPath _ _ thev = force (a @@ i) in thev in VLine (a' VI1 @@ VI1) (u' VI1) (v' VI1) $ fun \j -> comp (fun \x -> a' x @@ x) (phi `ior` j `ior` inot j) (system \i isone -> mkVSystem (Map.fromList [ (phi, ielim (a' VI0) (u' VI0) (v' VI0) (u @@ i @@ isone) j) , (j, v' i) , (inot j, u' i)])) (incS (a' VI0 @@ VI0 @@ j) phi (ielim (a' VI0 @@ VI0) (u' VI0) (v' VI0) a0 j)) VGlueTy _ thePhi theTypes theEquivs -> let b = u b0 = a0 fam = a in let base i = let VGlueTy b _ _ _ = forceAndGlue (fam @@ i) in b phi i = substitute (Map.singleton name i) thePhi types i = substitute (Map.singleton name i) theTypes @@ VReflStrict VI VI1 equivs i = substitute (Map.singleton name i) theEquivs a i u = unglue (base i) (phi i) (types i) (equivs i) (b @@ i @@ u) a0 = unglue (base VI0) (phi VI0) (types VI0) (equivs VI0) b0 del = faceForall phi a1' = comp (line base) psi (system a) (incS (base VI0) psi a0) t1' = comp (line (const (types VI0))) psi (line (b @@)) (incS (base VI0) psi b0) (omega_st, omega_t, omega_rep) = pres types base equivs psi (b @@) b0 omega = outS omega_t psi omega_rep omega_st (t1alpha_st, t1a_t, t1a_rep) = opEquiv (base VI1) (types VI1) (equivs VI1 @@ VReflStrict VI VI1) (del `ior` psi) (fun ts) (fun ps) a1' t1alpha = outS t1a_t (del `ior` psi) t1a_rep t1alpha_st (t1, alpha) = (vProj1 t1alpha, vProj2 t1alpha) ts isone = mkVSystem . Map.fromList $ [(del, t1'), (psi, (b @@ VI1 @@ isone))] ps _isone = mkVSystem . Map.fromList $ [(del, omega), (psi, VLine (line (const (base VI1))) a1' a1' (fun (const a1')))] a1 = comp (fun (const (base VI1))) (del `ior` psi) (system \j _u -> mkVSystem (Map.fromList [ (del, ielim (base VI1) a1' (vProj1 (equivs VI1 @@ VReflStrict VI VI1)) alpha j) , (psi, a psi _u) ])) (incS (base VI1) (phi VI1 `ior` psi) a1') b1 = glueElem (base VI1) (phi VI1) (types VI1) (equivs VI1) (fun (const t1)) (incS (base VI1) (ior (del `ior` psi) (inot del `iand` inot psi)) a1) in b1 VType -> VGlueTy a0 phi (fun' "is1" \is1 -> u @@ VI1 @@ is1) (fun' "is1" \_ -> mapVSystem (makeEquiv equivVar) (u @@ VVar equivVar @@ VReflStrict VI VI1)) VNe (HData False _) Seq.Empty -> a0 VNe (HData False _) args -> case force a0 of VNe (HCon con_type con_name) con_args -> VNe (HCon con_type con_name) $ compConArgs makeSetFiller (length args) (a @@) con_type con_args phi u _ -> VComp a phi u (incS (a @@ VI0) phi a0) VNe (HData True name) args -> compHIT name (length args) (a @@) phi u incA0 _ -> VComp a phi u (incS (a @@ VI0) phi a0) where {-# NOINLINE name #-} name :: Name name = unsafePerformIO newName {-# NOINLINE equivVar #-} equivVar :: Name equivVar = unsafePerformIO newName mapVSystem :: (Value -> Value) -> Value -> Value mapVSystem f (VSystem fs) = VSystem (fmap f fs) mapVSystem f x = f x forceAndGlue :: Value -> Value forceAndGlue v = case force v of v@VGlueTy{} -> v y -> VGlueTy y VI1 (fun (const y)) (fun (const (idEquiv y))) compHIT :: HasCallStack => Name -> Int -> (NFEndp -> NFSort) -> NFEndp -> Value -> Value -> Value compHIT name n a phi u a0 = case force phi of VI1 -> u @@ VI1 @@ VReflStrict VI VI1 VI0 | n == 0 -> outS (a VI0) phi u a0 | regular -> a0 | otherwise -> transHit name a VI0 (outS (a VI0) phi u a0) x -> go n a x u a0 where go 0 a phi u a0 = VHComp (a VI0) phi u a0 go _ a phi u a0 = VHComp (a VI1) phi (system \i n -> transSqueeze name a VI0 (\i -> u @@ i @@ n) i) (transHit name a VI0 (outS (a VI0) phi (u @@ VI1 @@ VReflStrict VI VI1) a0)) regular = a VI0 == a VI1 compConArgs :: (Name -> Int -> Value -> t1 -> t2 -> Value -> Value) -> Int -> (Value -> Value) -> Value -> Seq.Seq Projection -> t1 -> t2 -> Seq.Seq Projection compConArgs makeFiller total_args fam = go total_args where go _ _ Seq.Empty _ _ = Seq.Empty go nargs (VPi p dom (Closure _ rng)) (PApp p' y Seq.:<| xs) phi u | nargs > 0 = assert (p == p') $ PApp p' (nthArg (total_args - nargs) (fam VI1)) Seq.:<| go (nargs - 1) (rng (smuggle (fun (\i -> nthArg (total_args - nargs) (fam i))))) xs phi u | otherwise = assert (p == p') $ let fill = makeFiller typeArgument nargs dom phi u y in PApp p' (fill @@ VI1) Seq.:<| go (nargs - 1) (rng fill) xs phi u go _ _ _ _ _ = error $ "invalid constructor" smuggle x = VNe (HData False typeArgument) (Seq.singleton (PApp P.Ex x)) typeArgument = unsafePerformIO newName {-# NOINLINE typeArgument #-} makeSetFiller :: Name -> Int -> Value -> NFEndp -> Value -> Value -> Value makeSetFiller typeArgument nth (VNe (HData _ n') args) phi u a0 | n' == typeArgument = fun $ fill (makeDomain args) phi (system \i is1 -> nthArg nth (u @@ i @@ is1) ) a0 where makeDomain (PApp _ x Seq.:<| xs) = fun \i -> foldl (\t (~(PApp _ x)) -> t @@ (x @@ i)) (x @@ i) xs makeDomain _ = error "somebody smuggled something that smells" makeSetFiller _ _ _ _ _ a0 = fun (const a0) nthArg :: Int -> Value -> Value nthArg i (force -> VNe hd s) = case s Seq.!? i of Just (PApp _ t) -> t _ -> error $ "invalid " ++ show i ++ "th argument to data type " ++ show hd nthArg i (force -> VSystem vs) = VSystem (fmap (nthArg i) vs) nthArg i xs = error $ "can't get " ++ show i ++ "th argument of " ++ show (prettyTm (quote xs)) system :: (Value -> Value -> Value) -> Value system k = VLam P.Ex $ Closure (Bound "i" 0) \i -> VLam P.Ex $ Closure (Bound "[i]" 0) \isone -> k i isone fill :: DebugCallStack => NFLine -> NFEndp -> Value -> Value -> NFEndp -> Value fill a phi u a0 j = comp (line \i -> a @@ (i `iand` j)) (phi `ior` inot j) (system \i isone -> mkVSystem (Map.fromList [ (phi, u @@ (i `iand` j) @@ isone) , (inot j, outS a phi (u @@ VI0) a0)])) a0 hComp :: DebugCallStack => NFSort -> NFEndp -> Value -> Value -> Value hComp _ (force -> VI1) u _ = u @@ VI1 @@ VReflStrict VI VI1 hComp a phi u a0 = VHComp a phi u a0 glueType :: DebugCallStack => NFSort -> NFEndp -> NFPartial -> NFPartial -> Value glueType a phi tys eqvs = VGlueTy a phi tys eqvs glueElem :: DebugCallStack => NFSort -> NFEndp -> NFPartial -> NFPartial -> NFPartial -> Value -> Value glueElem _a (force -> VI1) _tys _eqvs t _vl = t @@ VReflStrict VI VI1 glueElem _a _phi _tys _eqvs _t (force -> VInc _ _ (force -> VUnglue _ _ _ _ vl)) = vl glueElem a phi tys eqvs t vl = VGlue a phi tys eqvs t vl unglue :: DebugCallStack => NFSort -> NFEndp -> NFPartial -> NFPartial -> Value -> Value unglue _a (force -> VI1) _tys eqvs x = vProj1 (eqvs @@ VReflStrict VI VI1) @@ x unglue _a _phi _tys _eqvs (force -> VGlue _ _ _ _ t vl) = outS _a _phi (t @@ VReflStrict VI VI1) vl unglue a phi tys eqvs (force -> VSystem fs) = VSystem (fmap (unglue a phi tys eqvs) fs) unglue a phi tys eqvs vl = VUnglue a phi tys eqvs vl faceForall :: (NFEndp -> NFEndp) -> Value faceForall phi = T.length (getNameText name) `seq` go (phi (VVar name)) where {-# NOINLINE name #-} name = unsafePerformIO newName go x@(VVar n) | n == name = VI0 | otherwise = x go x@(VINot (VVar n)) | n == name = VI0 | otherwise = x go (VIAnd x y) = iand (go x) (go y) go (VIOr x y) = ior (go x) (go y) go (VINot x) = inot (go x) go vl = vl isContr :: Value -> Value isContr a = exists' "x" a \x -> dprod' "y" a \y -> VPath (line (const a)) x y fiber :: NFSort -> NFSort -> Value -> Value -> Value fiber a b f y = exists' "x" a \x -> VPath (line (const b)) y (f @@ x) isEquiv :: NFSort -> NFSort -> Value -> Value isEquiv a b f = dprod' "y" b \y -> isContr (fiber a b f y) equiv :: NFSort -> NFSort -> Value equiv a b = GluedVl (HCon VType (Defined (T.pack "Equiv") (-1))) sp $ exists' "f" (a ~> b) \f -> isEquiv a b f where sp = Seq.fromList [ PApp P.Ex a, PApp P.Ex b ] pres :: (NFEndp -> NFSort) -> (NFEndp -> NFSort) -> (NFEndp -> Value) -> NFEndp -> (NFEndp -> Value) -> Value -> (Value, NFSort, Value) pres tyT tyA f phi t t0 = (incS pathT phi (VLine (tyA VI1) c1 c2 (line path)), pathT, fun $ \u -> VLine (fun (const (tyA VI1))) c1 c2 (fun (const (f VI1 @@ (t VI1 @@ u))))) where pathT = VPath (fun (const (tyA VI1))) c1 c2 c1 = comp (line tyA) phi (system \i u -> f i @@ (t i @@ u)) (incS (tyA VI0) phi (f VI0 @@ t0)) c2 = f VI1 @@ comp (line tyT) phi (system \i u -> t i @@ u) t0 a0 = f VI0 @@ t0 v = fill (fun tyT) phi (system \i u -> t i @@ u) t0 path j = comp (fun tyA) (phi `ior` j) (system \i _ -> f i @@ (v i)) (incS (tyA VI0) phi a0) opEquiv :: HasCallStack => Value -> Value -> Value -> NFEndp -> Value -> Value -> Value -> (Value, NFSort, Value) opEquiv aT tT f phi t p a = (incS ty phi v, ty, fun \u -> VPair (t @@ u) (p @@ u)) where fn = vProj1 f ty = exists' "f" tT \x -> VPath (line (const aT)) a (fn @@ x) v = contr ty (vProj2 f @@ a) phi (\u -> VPair (t @@ u) (p @@ u)) contr :: HasCallStack => Value -> Value -> NFEndp -> (Value -> Value) -> Value contr a aC phi u = comp (line (const a)) (ior phi (inot phi)) (system \i is1 -> mkVSystem $ Map.fromList [ (phi, ielim (line (const a)) (vProj1 aC) (u is1) (vProj2 aC @@ u is1) i) , (inot phi, vProj1 aC) ]) (incS a phi (vProj1 aC)) transp :: (NFEndp -> Value) -> Value -> Value transp line a0 = comp (fun line) VI0 (system \_ _ -> VSystem mempty) (incS (line VI0) VI0 a0) gtrans :: (NFEndp -> Value) -> NFEndp -> Value -> Value gtrans line phi a0 = comp (fun line) phi (system \_ _ -> mkVSystem (Map.singleton phi a0)) (incS (line VI0) VI0 a0) transHit :: Name -> (NFEndp -> Value) -> NFEndp -> Value -> Value transHit name line phi x = transHit name line phi (force x) where transHit name line phi (VHComp _ psi u u0) = VHComp (line VI1) psi (system \i j -> transHit name line phi (u @@ i @@ j)) (transHit name line phi (outS (line VI0) phi u u0)) transHit name line phi (VNe (HCon con_type con_name) spine) | ourType = x' where x' = VNe (HCon con_type con_name) $ compConArgs (makeTransFiller name) nargs line con_type spine phi () (_, force -> VNe hd (length -> nargs)) = unPi con_type ourType = case hd of HData True n' -> n' == name _ -> False transHit name line phi (VNe (HPCon sys con_type con_name) spine) | ourType = x' where x' = VNe (HPCon (mapVSystem rec sys) con_type con_name) $ compConArgs (makeTransFiller name) nargs line con_type spine phi () rec = transHit name line phi (_, force -> VNe hd (length -> nargs)) = unPi con_type ourType = case hd of HData True n' -> n' == name _ -> False transHit name line phi (VSystem xs) = mkVSystem (fmap (transHit name line phi) xs) transHit _ line phi a0 = gtrans line phi a0 transFill :: Name -> (NFEndp -> Value) -> NFEndp -> Value -> NFEndp -> Value transFill name a phi a0 i = transHit name (\j -> a (iand i j)) (phi `ior` inot i) a0 where transSqueeze :: Name -> (NFEndp -> Value) -> NFEndp -> (NFEndp -> Value) -> NFEndp -> Value transSqueeze name a phi x i = transHit name (\j -> a (ior i j)) (phi `ior` i) (x i) makeTransFiller :: Name -> Name -> p -> Value -> NFEndp -> () -> Value -> Value makeTransFiller thedata typeArgument _ (VNe (HData _ n') args) phi () a0 | n' == typeArgument = fun (transFill thedata (makeDomain args) phi a0) where makeDomain (PApp _ x Seq.:<| xs) = \i -> foldl (\t (~(PApp _ x)) -> t @@ (x @@ i)) (x @@ i) xs makeDomain _ = error "somebody smuggled something that smells" makeTransFiller _ _ _ _ _ _ a0 = fun (const a0) makeEquiv :: Name -> Value -> Value makeEquiv var vne = makeEquiv' \x -> substitute (Map.singleton var x) vne makeEquiv' :: (NFEndp -> Value) -> Value makeEquiv' line' = VPair f $ fun \y -> VPair (fib y) (fun \u -> p (vProj1 u) (vProj2 u) y) where line = fun \i -> line' (inot i) a = line @@ VI0 b = line @@ VI1 f = fun \x -> transp (line @@) x g = fun \x -> transp ((line @@) . inot) x u i = fun \x -> fill line VI0 (system \_ _ -> mkVSystem mempty) (incS a VI0 x) i v i = fun \x -> fill (fun ((line @@) . inot)) VI0 (system \_ _ -> mkVSystem mempty) (incS a VI1 x) (inot i) fib y = VPair (g @@ y) (VLine b y (f @@ (g @@ y)) (fun (theta0 y VI1))) theta0 y i j = fill line (ior j (inot j)) (system \i _ -> mkVSystem (Map.fromList [(j, v i @@ y), (inot j, u i @@ (g @@ y))])) (incS a (ior j (inot j)) (g @@ y)) i theta1 x beta y i j = fill (fun ((line @@) . inot)) (ior j (inot j)) (system \i _ -> mkVSystem (Map.fromList [ (inot j, v (inot i) @@ y) , (j, u (inot i) @@ x)])) (incS b (ior j (inot j)) (ielim b y (f @@ x) beta y)) (inot i) omega x beta y = theta1 x beta y VI0 delta x beta y j k = comp line (ior k (ior (inot k) (ior j (inot j)))) (system \i _ -> mkVSystem (Map.fromList [ (inot k, theta0 y i j) , (k, theta1 x beta y i j) , (inot j, v i @@ y) , (j, u i @@ omega x beta y k)])) (incS a (ior k (ior (inot k) (ior j (inot j)))) (omega x beta y (iand j k))) p x beta y = VLine (exists a \x -> VPath b y (f @@ x)) (fib y) (VPair x beta) $ fun \k -> VPair (omega x beta y k) (VLine (VPath b y (f @@ x)) (vProj2 (fib y)) beta $ fun \j -> delta x beta y j k) idEquiv :: NFSort -> Value idEquiv a = VPair idfun idisequiv where idfun = fun id u_ty = exists' "y" a \x -> VPath (fun (const a)) x x idisequiv = fun \y -> VPair (id_fiber y) $ fun \u -> VLine u_ty (id_fiber y) u $ fun \i -> VPair (ielim (fun (const a)) y y (vProj2 u) i) $ VLine (fun (const a)) y (vProj1 u) $ fun \j -> ielim (fun (const a)) y y (vProj2 u) (iand i j) id_fiber y = VPair y (VLine a y y (fun (const y))) strictK :: DebugCallStack => Value -> Value -> Value -> Value -> Value -> Value strictK _ _ _ pr (VReflStrict _ _) = pr strictK a x bigp pr (VNe h sp) = VNe h (sp Seq.:|> PK a x bigp pr) strictK a x bigp pr (VCase env rng sc cases) = VCase env rng sc (map (projIntoCase func) cases) where func = AxK (quote a) (quote x) (quote bigp) (quote pr) strictK a x bigp pr (GluedVl h sp vl) = GluedVl h (sp Seq.:|> PK a x bigp pr) (strictK a x bigp pr vl) strictK _ _ _ _r eq = error $ "can't K " ++ show (prettyVl eq) strictJ :: DebugCallStack => Value -> Value -> Value -> Value -> Value -> Value -> Value strictJ _a _x _bigp pr _ (VReflStrict _ _) = pr strictJ a x bigp pr y (VNe h sp) = VNe h (sp Seq.:|> PJ a x bigp pr y) strictJ a x bigp pr y (VCase env rng sc cases) = VCase env rng sc (map (projIntoCase func) cases) where func = AxJ (quote a) (quote x) (quote bigp) (quote pr) (quote y) strictJ a x bigp pr y (GluedVl h sp vl) = GluedVl h (sp Seq.:|> PJ a x bigp pr y) (strictJ a x bigp pr y vl) strictJ _ _ _ _r _ eq = error $ "can't J " ++ show eq projIntoCase :: (Term -> Term) -> (Term, Int, Term) -> (Term, Int, Term) projIntoCase fun (pat, nLams, term) = (pat, nLams, go nLams term) where go 0 x = fun x go n (Lam p x r) = Lam p x (go (n - 1) r) go n (PathIntro l a b r) = PathIntro l a b (go (n - 1) r) go _ x = error $ show $ prettyTm x